DE69609693T3 - Mold for piston casting and piston casting using this mold. - Google Patents

Description

The The present invention relates to an improved ring carrier which to improve the wear resistance in the piston ring grooves from piston for Internal combustion engines and in particular of pistons is used, made of cast aluminum alloys are made. The present invention also relates to a method that the ring bearer integrally molded into an aluminum alloy piston, and a piston tool.

In This description uses the term "ring carrier" to designate all of those ring carriers before they are integrally molded into the piston, ring carriers, the have been integrally cast into the piston, and ring carriers used, which have been finished by means of machining.

Ringbearer, the generally made of stainless steel or cast niresist for pistons off Aluminum alloy used to the wear resistance to improve the mounting groove of the piston ring.

If such a piston is poured, the ring carrier is in the Form used and the ring carrier is by filling molded integral with a molten aluminum alloy. conventional is on the outer circumference of the ring bearer a ring-shaped Ring flange formed with a rectangular cross section, so that the Ring can be fixed in the mold and fixed.

Generally The following processes involve the pouring of a ring carrier. Of the Ring bearer becomes previously immersed in molten aluminum to a suitable Bonding layer between the ring carrier and the aluminum. The bonding layer with aluminum is over the entire surface of the ring bearer produced. Then the ring carrier is fixed in the mold, that between the fixed in the form of ring carrier and the outer shape of excess space so that the entire ring carrier is completely detached from the mold cast into the mold, can be surrounded by molten metal. Thus, the ring carrier is poured and metallurgically connected to the aluminum alloy piston.

If a ring bearer with a flange as described above is used the maximum outside diameter of the ring bearer bigger than that of the piston. This requires that the piston casting must have a larger outer diameter. This means a waste of raw materials and is uneconomical. Furthermore, the accuracy in the attachment of the ring carrier on reduces the shape and automation of the fastening process is difficult. To go around the flange at the piston casting considerable excess masses lost. This makes extra Steps required at the machining stage around the excess mass too eliminate, and also has a large amount of chips to Result, the mixtures of aluminum and Niresist cast iron or stainless steel.

The JP-A-30 102 248 discloses a method of casting a piston with a wear resistant Ring for forming a groove and an element, which thus by the Circumferentially spaced connecting elements is connected to enable that a cooling cavity is formed.

The GB-A-2090780 discloses a method of casting a piston with a piston wear resistant Commitment. The ring is passed through a peripheral edge in the mold cavity held.

The US-A-2,851,318 discloses a ring carrier for use in a Piston casting tool having fixing pins, wherein the ring carrier with an outer surface with a groove for receiving ends of the pins. The revelation This document corresponds to the introduction to claim 1.

task The present invention is intended to solve the problems of the above-described Cope with the state of the art. Another object of the present invention is to provide a novel Ringbearer and a novel method of casting pistons with the following To create properties: the production is economical as the maximum outer diameter of the ring bearer approximately equal to that of the cast piston, thereby reducing raw material costs be reduced; the ring bearer can be attached to the mold automatically with high accuracy; the cast piston has minimal excess mass, so no Material is wasted and no excess machining are required, and the amount of waste chips is minimized.

According to a first aspect of the present invention, there is provided a piston casting tool comprising:
a piston molding that defines a piston cavity of the casting tool,
at least one fixed fixing pin, which is attached to the piston casting tool on an inner wall of the piston molding,
at least one movable locator pin movably attached to the piston blank so that the at least one movable locator pin is movable through the inner wall in a substantially radial direction with respect to a center of the piston cavity, each one of the chambers at least one movable fixing pin and the at least one fixed fixing pin has an innermost end in the direction of a center of the piston cavity,
an annular member having a V-shaped groove on an outer surface to receive the innermost end of the at least one fixed fixing pin and the at least one movable fixing pin,
a driving device that urges the at least one movable fixing pin toward the center of the piston cavity along the substantially radial direction, so that the annular member from the innermost end of the at least one fixed fixing pin and the innermost end of the at least one movable fixing pin at a prescribed position is held within the piston cavity,
means for receiving a molten metal in the piston cavity whereby a piston casting is formed with an internally cast-in ring carrier in a region of the piston casting surrounding the annular element.

The Tool can have an outer shape, an inner mold and an upper mold. In a preferred embodiment are the movable fixing pins along a single circumference a cylindrical Inner wall of the outer mold arranged. The movable fixing pins extending along the radial direction the inner wall of the outer mold can move in and out, are arranged at positions on the inner wall, the fixing position of the ring bearer in a piston. The drive device moves the movable fixing pins in and out of the inner wall of the outer mold along the radial direction. A ring bearer becomes at a prescribed position in the outer shape used and held there. The movable pins are forward moved in the direction of the central axis of the outer mold. The ends of the Fixing pins are on the thin Groove on the outer circumference adapted to the ring carrier. The Tools are then closed and it becomes a molten one Aluminum alloy poured into the mold. Thus, the ring carrier is in the piston cast.

It It is recommended that the for the movable fixing pins used driving device a spring or comprises an air cylinder.

embodiments The invention can be a approximately have rectangular cross section, on which a thin groove along the entire outer circumference is trained.

These thin groove can be longitudinal the entire outer peripheral surface of the Ringbearer be formed continuously, or it may be along a single circumference interrupted on the outer peripheral surface be educated.

When Material for the ring bearer becomes Niresist cast iron or stainless steel is recommended, but not on these materials limited.

According to a second aspect of the present invention, there is provided a method of casting a piston in a piston casting tool, as described above, comprising the steps of:
Extracting at least one movable fixing pin from a cavity of the piston casting tool,
Inserting an annular ring carrier having a V-shaped groove on an outer surface into the Kolbengießwerkzeug so that the groove is engaged with at least one fixed fixing pin in the Kolbengießwerkzeug,
Engaging the at least one movable locating pin in the groove by urging the at least one locatable locating pin toward the groove, thereby holding the annular carrier by the at least one locatable locating pin and the at least one fixed locating pin;
Closing the Kolbengießwerkzeugs, and
Pouring molten metal into the Kolbengießwerkzeug, whereby the ring carrier is integrally molded into the piston.

The The present invention configured as described above keeps material costs for the Ringbearer low and possible an automatic fixation of the ring carrier in the tool with a high Degree of accuracy. Furthermore, there is little excess mass on the piston casting. Thus are No additional Machining steps required, it will not be material wasted and no chip particles are generated. The present Invention allows a cost-effective Production of pistons and their execution has numerous advantages on.

The Above and other objects, features and advantages of the present invention The invention will become apparent from the following description taken in conjunction with the accompanying drawings, in which like reference numerals denote the same elements.

1 Fig. 12 is a partially cutaway front view showing an example of a widely used ring carrier of the prior art.

2 is a sectional view of the attached in a tool ring carrier of 1 shows.

3 is a partially cutaway front view showing an example of a Kolbengußstückes, with the in 2 cast tool was poured.

4 Fig. 16 is a partially cutaway front view showing an embodiment of the ring carrier of the present invention.

5 is a sectional view showing the ring carrier of 4 shows that is mounted in a tool.

6 Fig. 3 is a partially cutaway front view showing an example of a piston casting produced by using the in 5 cast tool was poured.

In 1 is a ring bearer 11 described in the prior art.

As in 1 shown comprises a ring carrier 11 According to the prior art, an annular main body 11a whose end view on a sectional plane rectangular to a tangent has an approximately rectangular shape. Along a circumference of the main body 11a is a flat flange 11b formed with a small vertical dimension.

In the example shown in the drawings is flange 11b at about the midpoint of the thickness of the main body 11a arranged. However, flange can 11b somewhere on the circumference of the main body 11a may be arranged, for example, at the upper end or the lower end of the main body 11a be arranged in the drawing.

As in 2 is shown is a ring bearer 11 used in a tool for casting pistons.

In 2 the tool is shown in a closed state, the ring carrier 11 is inserted into the tool.

The right half of the cross section of 2 shows the ring carrier held by a fixed attachment projection, but the left half of 2 shows that the ring carrier portion is held by no fixed attachment projection.

to Simplification of the drawing are the closure device for the tool, the release device for removing the casting and the casting device Not shown.

As in 2 is shown comprises a multi-part outer shape 12 a partial form 12-1 and a part form 12-2 , It is also an interior shape 13 and an upper mold 14 shown. Several fixed fastening projections 15 are at the outer shape 12 arranged to attach the ring carrier 11 permit.

Fixed fastening projections 15 are inserted and fixed in a plurality of insertion holes, which are arranged along a single circumference, which is selected according to the mounting position of the ring carrier. The insertion holes, which are radially oriented and symmetrical in the sidewalls of the outer mold 12 are arranged, serve the ring carrier 11 to keep when the outside shape 12 is closed.

To pour the ring carrier into a piston, the outer shape 12 closed and a ring bearer 11 on the upper surfaces of fixed fastening projections 15 attached. Then the upper form 14 at the upper part of the outer shape 12 attached, whereby the tools are closed.

As described above, the ring carrier 11 be surrounded over its entire surface with molten aluminum. Thus, the ring carrier 11 just pressed where it passes through fixed mounting protrusions 15 is held. As in the left half of 2 is shown, there is a free space between the ring carrier and the tools ( 14a . 12a ).

Thus, in the past, experienced workers had to pour a piston through the ring carrier 11 coaxial with the outer shell 12 was held.

However, using this prior art method, it is difficult even for skilled workers to cast a piston such that the ring carrier 11 completely coaxial with the outer shape 12 is held. The reject rate was high. Furthermore, the excess mass means that around the ring carrier 11 arranged flange 11b surrounds that the maximum outer diameter of the casting ends is considerably larger than the outer diameter required for the piston.

The ring bearer 11 is cut to separate pieces by using a lathe from a centrifugally cast cylindrical tube of Niresist iron or stainless steel. In a first processing step, the cast long cylinder barrel becomes on the inner and outer surfaces, ie, the surfaces that are the inner surface of the main body 11a of the ring bearer 11 and the outer surface of the flange 11b correspond, edited. Then, the surface of the free end face of the cylinder is completed on a lathe so as to be the reference surface for the ring carrier 11 can serve. The surfaces on both sides of the flange 11b are cut with a lathe to form a projection, and the two end faces and the end face of flange 11b will be completed. This completes the ring bearer 11 ,

If the ring bearer 11 In this mold, the Niresist casting serving as the base material must be quite thick. The mass of the cylinder tube is at least 1.5 times the mass of the finished ring carrier 11 , Thus, the amount of wasted material is significant.

The ring bearer 11 is manufactured on automatic high-speed lathes using the steps described above in mass production. Thus, a certain order of error in the thickness of the flange must 11b , the distance between the central surface of the flange and the end face serving as the reference surface and the outer diameter of the main body 11a if the flange 11b is not available. Further, as described above, the ring carrier must 11 be positioned exactly coaxial with the tool. Thus, the piston casting causes a considerable excess mass in this type of tool, as in 3 is shown.

Furthermore, if a permissible error for the eccentricity of the ring carrier 11 admitted in a piston, the ring carrier 11 even made thicker, so that the annular groove ensures that the annular groove is properly formed from the piston can properly pour the ring carrier with a certain eccentricity.

Thus, the ring carrier must 11 thicker than required and there is a significant amount of excess mass around the cast-in ring carrier in the piston. These problems cause waste materials and an increased number of machining steps.

On the other hand, as in 4 shown is a ring bearer 1 of the present invention, a main body 1a and a single V-shaped groove 1b formed on the outer periphery.

The ring bearer 1 can also be made of a cylindrical body made of Niresist cast iron or stainless steel. However, on the outer circumference of the main body 1a no flange formed, and a ring carrier 1 is exactly coaxial with an outer shape 2 held. Thus, if the ring carrier 1 is integrally poured into the flask, the excess mass on the outside to be made very thin. This reduces the amount of material required and is economical. Since the axial location of the ring carrier is accurately fixed, the present invention may as well be used for grooves of the "high top ring grooves".

In 5 is a tool shown for casting a piston with the ring carrier 1 is used.

This tool includes a multi-part outer shape 2 , the two partial forms 2-1 and 2-2 includes, a center shape 3 and an upper mold 4 ,

The part form 2-1 includes a movable fixing pin 5 and the part form 2-2 includes a fixed fixing pin 6 , In the drawings, each one of the movable fixing pin 5 and the fixed fixing pin 6 shown, but it may be a variety of these pens 5 and 6 be arranged so that for the ring bearer 1 a reliable holder can be provided.

As in 5 is shown, the movable fixing pin 5 always pressed by a drive device in the direction of the center of the tool, which is a casting 7 and a spring 8th includes. The movable fixing pin 5 carries the ring bearer 1 and presses the ring bearer 1 in the direction of the center of the tool, which is fixed to a position that the fixed fixing pin 6 opposite. Thus, the movable fixing pin works 5 with the fixed fixing pin 6 together to ensure correct positioning of the ring carrier 1 maintain.

In a comparison of 5 and 2 can be found that the outer shape 2 and the upper form 4 have a simpler shape than the outer shape 12 and the upper form 14 of the tool, that for the ring bearer 11 is used in the prior art. Thus, it is obvious that lower manufacturing costs and maintenance costs are required.

As in 6 is shown, a Kolbengußstück with this tool on no excess mass, which protrudes from the outer peripheral surface, and the pouring of the ring carrier is carried out while the ring carrier is held completely coaxial with the tool. Thus, the thickness of the excess mass can be kept to a minimum without producing defective products due to poor positioning of the Ringträ gers. This causes a very low reject rate. Also, given the thin groove 1b is accurately positioned, the cross-sectional dimensions of the ring carrier are kept to a minimum. Thus, waste material can be kept to a minimum and costs can be reduced.

Having described the preferred embodiments of the invention with reference to the accompanying drawings, it should be understood that the invention is not limited to such precise embodiments, and that various changes and modifications will occur to those skilled in the art without departing from the scope of the invention can be performed, which is defined in the appended claims.

For example the shape of the cross section of the ring carrier can be suitably chosen. For example must the Do not groove along the entire circumference of the ring carrier continuously be, but may be interrupted. The forms of the Tool, the movable pins and the fixed pins can also be freely modified as long as the tasks of the present Invention satisfied become.

Claims (4)

Piston casting tool ( 2 . 3 . 4 ) comprising: a piston molding that defines a piston cavity of the casting tool, at least one fixed fixing pin ( 6 ), which is attached to the piston casting tool on an inner wall of the piston molding, at least one movable fixing pin ( 5 ) movably mounted on the piston molding so that the at least one movable fixing pin is movable through the inner wall in a substantially radial direction with respect to a center of the piston cavity, each of the at least one movable fixing pin and the at least one solid fixing pin has an innermost end toward a center of the piston cavity, an annular member as a ring carrier ( 1 ), which has a V-shaped groove ( 1b ) on an outer surface to receive the innermost end of the at least one fixed fixing pin and the at least one movable fixing pin, a driving device ( 7 . 8th ) urging the at least one movable fixing pin toward the center of the piston cavity along the substantially radial direction, so that the annular member is fixed from the innermost end of the at least one fixing pin and the innermost end of the at least one movable fixing pin to a prescribed position of the piston cavity, means for receiving a molten metal in the piston cavity and thus forming a piston casting with an internally cast-in ring carrier in a region of the piston casting surrounding the annular element. Piston casting tool according to claim 1, wherein the groove ( 1b ) of the annular member is continuous along the outer surface of the annular member. piston casting according to claim 1, wherein the groove of the annular element along a single circumference on the outer surface of the annular element is not continuous. Method for casting a piston in a piston casting tool ( 2 . 3 . 4 ) according to claim 1, comprising the steps of: extracting at least one movable fixing pin ( 5 ) from a cavity of the Kolbengießwerkzeugs, inserting an annular ring carrier ( 1 ), which has a V-shaped groove ( 1b ) on an outer surface into the Kolbengießwerkzeug so that the groove with at least one fixed fixing pin ( 6 ) is engaged in the Kolbenzießwerkzeug, engaging the at least one movable fixing pin in the groove by the at least one movable fixing pin is pressed in the direction of the groove, whereby the ring carrier is held by the at least one movable fixing pin and the at least one fixed fixing pin, closing of the piston casting tool, and pouring molten metal into the Kolbengießwerkzeug, whereby the ring carrier is integrally molded into the piston.